Abstract:
A system includes a robotic arm, an imaging device coupled to the robotic arm, a tail positioner coupled to the robotic arm, and a processor. The imaging device captures imaging data of a rearview of a dairy livestock through a field of view of the imaging device. The tail positioner is able to move from a down position to an up position. The processor is coupled to both the imaging device and the tail positioner and is configured to identify a tail of the dairy livestock within the imaging data captured by the imaging device and send one or more instructions to raise the tail positioner from the down position to the up position, thereby moving the tail out of the field of view of the imaging device.
Abstract:
A robotic attacher retrieves first and second cups from the right side of an equipment area located behind a dairy livestock and attaches the cups to the teats of the dairy livestock in sequence. The sequence comprises attaching the first cup to the right front teat and a second cup to the left front teat of the dairy livestock. The robotic attacher retrieves third and fourth cups from the right side of the equipment area and attaches the cups to the teats of the dairy livestock in sequence. The sequence comprises attaching the third cup to the right rear teat and the fourth cup to the left rear teat.
Abstract:
A system includes a controller and a robotic arm. The controller accesses an image signal of an udder of a dairy livestock, and determines a spray position by processing the accessed image signal to determine a tangent at the rear of the udder and a tangent at the bottom of the udder. The spray position is a position relative to the intersection of the two tangents. A robotic arm communicatively coupled to the controller positions a spray tool at the spray position.
Abstract:
A system includes a milking stall to accommodate a dairy livestock and a robotic attacher. The robotic attacher extends under the dairy livestock and comprises a nozzle. The robotic attacher is operable to rotate such that, during a first operation, the nozzle is positioned generally on the bottom of the robotic attacher, and during a second operation, the nozzle is positioned generally on the top of the robotic attacher.
Abstract:
A method for operating a robotic arm, comprises determining a speed of rotation of a rotary milking platform, the rotary milking platform having a stall for a dairy livestock. The method continues by moving a carriage along a track positioned adjacent to the rotary milking platform at a rate that is based at least in part upon the determined speed of rotation of the rotary milking platform, wherein the carriage moves independently of the rotary milking platform and in a direction corresponding to a direction of rotation of the rotary milking platform. The method continues by extending a robotic arm that is coupled to the carriage between the legs of the dairy livestock, wherein the robotic arm remains extended between the legs of the dairy livestock for a period of time as the stall rotates adjacent to the robotic arm. The method concludes by retracting the robotic arm from between the legs of the dairy livestock as the stall rotates adjacent to the robotic arm.
Abstract:
A method for operating a robotic arm, comprises determining a speed of rotation of a rotary milking platform, the rotary milking platform having a stall for a dairy livestock. The method continues by moving a carriage along a track positioned adjacent to the rotary milking platform at a rate that is based at least in part upon the determined speed of rotation of the rotary milking platform, wherein the carriage moves independently of the rotary milking platform and in a direction corresponding to a direction of rotation of the rotary milking platform. The method continues by extending a robotic arm that is coupled to the carriage between the legs of the dairy livestock, wherein the robotic arm remains extended between the legs of the dairy livestock for a period of time as the stall rotates adjacent to the robotic arm. The method concludes by retracting the robotic arm from between the legs of the dairy livestock as the stall rotates adjacent to the robotic arm.
Abstract:
The invention relates to a conduit for transferring milk. The conduit is provided with at least one flexible wall, which divides the conduit into at least one milk duct and at least one secondary duct. The milk duct and the at least one secondary duct extend along a longitudinal axis of the conduit, it being possible for the at least one milk duct to be substantially emptied by pressing through filling the at least one secondary duct.
Abstract:
A rotary milking platform (1) comprises a plurality of apparatus, each of which comprises a platform (11) which forms a segment of the rotary platform (1). The platforms (11) define respective animal accommodating locations (3) for animals to be milked. A communicating opening (20) in each platform (11) is closed by a pair of closure plates (25) which are pivotal upwardly into an open state for separating the hind legs of an animal. A carriage (14) which is slideably carried beneath the platform (11) of each apparatus (10) in the directions of the arrows A and B. A teat cup carrier (15) is pivotally mounted in the carriage (14) of each apparatus (10) and is pivotal from a first state with teat cups (16) in the carrier (15) in a protective state extending horizontally and a second state with the teat cups (16) in a ready state extending vertically upwardly and ready for manual placement onto the teats of an animal. The carriage (14) is urgeable into a first position with the teat cup carrier (15) in the first state and with the teat cups (16) sealably engaged in plug elements (45) which include jetters (47) for use in rinsing and washing the milking system. The carriage (14) is moveable from the first position to a second position with the teat cup carrier (15) substantially aligned with the udder of an animal so that when the teat cup carrier (15) is urged into the second state, the teat cups (16) can be manually urged upwardly by hand and attached to the teat of the animal.
Abstract:
A system for operating a robotic arm comprises a carriage and a robotic arm. The carriage is mounted on a track adjacent to a rotary milking platform having a substantially circular perimeter and a stall for a dairy livestock. The carriage moves along a substantially straight portion of the track tangent to and outside the perimeter of the rotary milking platform at a rate based at least in part upon a speed of rotation of the rotary milking platform. The carriage moves in a direction corresponding to the direction of rotation of the rotary milking platform and such movement of the carriage is independent of any physical coupling between the carriage and the rotary milking platform. The robotic arm extends between the legs of the dairy livestock.
Abstract:
A robotic attacher retrieves a preparation cup from an equipment area of a milking box located behind a dairy livestock. The robotic attacher attaches and detaches the preparation cup to the teats of the dairy livestock in sequence. The sequence comprises attaching and detaching the preparation cup to the right front teat, the left front teat, the left rear teat, and the right rear teat.